Light receiving apparatus

ABSTRACT

Provided is a light receiving apparatus including a first light receiving unit; a body to which the first light receiving unit is secured; a first exterior portion that covers at least a portion of the body; and a mount that is capable of having an interchangeable lens attached thereto, to which the body and the first exterior portion are secured. Also provided is a light receiving apparatus, in which a body to which a first light receiving unit is secured and a first exterior portion that covers at least a portion of the body are secured to a mount that is capable of having an interchangeable lens attached thereto, and force placed on the first exterior portion is absorbed by the mount, such that transfer of the force placed on the first exterior portion to the body is reduced.

This application is a continuation application of U.S. patentapplication Ser. No. 14/854,808, filed Sep. 15, 2015, which is acontinuation application, filed under 35 U.S.C. § 111(a), ofInternational Application PCT/JP2014/001157, filed Mar. 3, 2014, whichclaims the priority benefit of Japanese Patent Application 2013-054441,filed Mar. 15, 2013, the disclosures of which are hereby incorporated byreference in their entirety.

BACKGROUND 1. Technical Field

The present invention relates to a light receiving apparatus.

2. Related Art

A camera is known in which a mirror box supporting an imaging element issupported on a main frame that is the main structure of the camera bodyby a shock resistant support member.

Patent Document 1: Japanese Patent Application Publication No.2005-215014

However, there is a problem that components to which the opticalelements are secured are prone to receiving stress from the outside.

SUMMARY

According to a first aspect of the present invention, provided is alight receiving apparatus comprising a first light receiving unit; abody to which the first light receiving unit is secured; a firstexterior portion that covers at least a portion of the body; and a mountthat is capable of having an interchangeable lens attached thereto, towhich the body and the first exterior portion are secured.

The summary clause does not necessarily describe all necessary featuresof the embodiments of the present invention. The present invention mayalso be a sub-combination of the features described above.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view schematically showing the outer appearanceof an imaging device 10.

FIG. 2 is an exploded perspective view schematically showing theassembly of the imaging device 10.

FIG. 3 is an exploded perspective view schematically showing theassembly of the body 100, the body-side mount 200, and the front cover300.

FIG. 4 is an exploded perspective view of the imaging device 10.

FIG. 5 is a cross-sectional view obtained by cutting the imaging device10 in the xy plane.

FIG. 6 is an exploded perspective view schematically showing assembly ofthe front cover 300, the top cover 400, the back cover 500, and thesuspension ring 600.

FIG. 7 is an exploded perspective view showing a state in which thesuspension ring 600 is positionally fixed to the top cover 400.

FIG. 8 is an exploded perspective view schematically showing theassembly of the front cover 300, the back cover 500, and a tripod base700.

FIG. 9 is a cross-sectional view of a yz cross section schematicallyshowing a state in which the tripod base 700 is assembled with the frontcover 300 and the back cover 500.

FIG. 10 is a perspective view of a portion of the back cover 500.

FIG. 11 is an exploded perspective view schematically showing anotherassembly example of the tripod base assembly.

FIG. 12 is an exploded perspective view schematically showing anotherassembly example of the tripod base assembly.

DESCRIPTION OF EXEMPLARY EMBODIMENTS

Hereinafter, some embodiments of the present invention will bedescribed. The embodiments do not limit the invention according to theclaims, and all the combinations of the features described in theembodiments are not necessarily essential to means provided by aspectsof the invention.

FIG. 1 is a perspective view schematically showing the outer appearanceof an imaging device 10. FIG. 1 mainly shows the structural componentsof the imaging device 10. The imaging device 10 is a camera body of asingle-lens reflex camera. The imaging device 10 includes a body 100, abody-side mount 200, a front cover 300, a top cover 400, a back cover500, a suspension ring 600, and a substrate cover 800.

As described further below, an imaging unit is secured to the body 100.The body-side mount 200 has an interchangeable lens attached thereto.When describing the configuration of the imaging device 10, thedirection along the optical axis of the interchangeable lens apparatusis defined as the z axis direction. In other words, the direction of anincident subject light beam is defined as the z axis direction. Thedirection in which the subject light beam is incident is defined as thenegative z axis direction, and the opposite of this direction is definedas the positive z axis direction. Furthermore, the directions shown inFIG. 1 are defined as the x axis direction and the y axis direction. Thex axis, the y axis, and the z axis form an orthogonal right-handedcoordinate system. There may be cases where the positive z axisdirection is referred to as “forward” or “toward the front.”Furthermore, there may be cases where the negative z axis direction isreferred to as “backward” or “toward the back.” There may be cases wherethe positive y axis direction is referred to as “upward” or “toward thetop.” There may be cases where the negative y axis direction is referredto as “downward” or “toward the bottom.”

FIG. 2 is an exploded perspective view schematically showing theassembly of the imaging device 10. FIG. 2 schematically shows theassembly of the body 100, the body-side mount 200, the front cover 300,the top cover 400, and the back cover 500.

The following is a basic description of the structure of the imagingdevice 10. The front cover 300 covers at least a portion of the body100. The body 100 is substantially covered by the front cover 300, thetop cover 400, and the back cover 500. The front cover 300, the topcover 400, and the back cover 500 are formed of resin. The front cover300, the top cover 400, and the back cover 500 are formed by resinmolding. The body-side mount 200 is formed of metal. The body-side mount200 is a mount ring shaped as a ring. The body 100 is formed of resin.

As described further below, the body-side mount 200 is secured to thebody 100, along with the front cover 300, for example. By securing thebody-side mount 200 to the front cover 300, the stiffness of theposition on the front cover 300 where the body-side mount 200 is securedis increased. Accordingly, the front cover 300 is secured at a positionon the body 100 that has high stiffness. The body 100 is not secured toany of the front cover 300, the top cover 400, and the back cover 500 atany other location. The front cover 300, the top cover 400, and the backcover 500 have a monocoque structure. The front cover 300, the top cover400, and the back cover 500 are connected to each other by a spigotstructure at contact surfaces. Accordingly, the stress placed on any oneof the front cover 300, the top cover 400, and the back cover 500 can bereceived by the entire structure including the front cover 300, the topcover 400, and the back cover 500, and the stress is transferred in amanner to be focused on the portion of the body 100 having increasedstiffness due to the securing of the body-side mount 200. Therefore, theeffect that the stress placed on any one of the front cover 300, the topcover 400, and the back cover 500 has on the positioning accuracy of theimaging unit secured to the body 100 can be reduced.

FIG. 3 is an exploded perspective view schematically showing theassembly of the body 100, the body-side mount 200, and the front cover300.

The body 100 has an overall box shape. The body 100 includes a frontsurface 101 and a back surface 102 that is on the opposite side of thefront surface 101. The back surface 102 is positioned farther in thenegative z axis direction than the front surface 101.

An imaging unit 160, which is described further below, is secured to theback surface 102 of the body 100. Specifically, a bracket 170 is securedto the back surface 102 of the body 100. For example, the bracket 170 isfastened to the body 100 on the back surface 102. The imaging unit 160described further below is secured to the bracket 170. In addition tothe imaging unit 160, a mirror unit, a shutter unit, a finder unit, afocal point detection unit, and the like are secured to the body 100.The finder unit is secured to the top surface 104 of the body 100. Thefocal point detection unit is secured to the bottom surface 105, whichis a surface of the body 100 on the side opposite the top surface 104. Apower supply unit 840 that is described further below and variousmanipulation components are attached to the front cover 300.

The body 100 includes a securing section 110 to which the body-sidemount 200 is secured. The securing section 110 protrudes in the positivez axis direction beyond the front surface 101. The securing section 110has a first surface 150 that protrudes in the positive z axis directionbeyond a second surface 158 of the front surface 101, which is parallelto the xy plane. The securing section 110 has a substantially circularshape in the xy plane. The securing section 110 has a substantiallycylindrical shape.

A recessed portion 112, a recessed portion 114, and a recessed portion116 are formed in the first surface 150 of the securing section 110. Therecessed portion 112 has a floor portion 142. The recessed portion 114has a floor portion 144. The recessed portion 116 has a floor portion146. The first surface 150 is positioned farther in the positive z axisdirection than the floor portion 142, the floor portion 144, and thefloor portion 146.

A convex portion 113 is formed between the recessed portion 112 and therecessed portion 114 in the securing section 110. A convex portion 115is formed between the recessed portion 114 and the recessed portion 116.A convex portion 111 is formed between the recessed portion 116 and therecessed portion 112. The first surface 150 forms a top surface 151 ofthe convex portion 111, a top surface 153 of the convex portion 113, anda top surface 155 of the convex portion 115.

A hole 121 is formed on the top surface 151 of the convex portion 111. Ahole 123 is formed on the top surface 153 of the convex portion 143. Ahole 125 is formed on the top surface 155 of the convex portion 145. Ascrew 231 is inserted through the hole 121. A screw 233 is insertedthrough the hole 123. A screw 235 is inserted through the hole 125.

A hole 122 is formed in the floor portion 142. A hole 124 is formed inthe floor portion 144. A hole 126 is formed in the floor portion 146. Ascrew 232 is inserted through the hole 122. A screw 234 is insertedthrough the hole 124. A screw 236 is inserted through the hole 126.

The body-side mount 200 has a mounting surface 201 that is the surfaceon which the interchangeable lens is attached, a mount securing surface203 that is the surface on the opposite side from the mounting surface201, a side surface 202 that is the surface between the mounting surface201 and the mount securing surface 203, and a side surface 204 that isthe surface on the opposite side from the side surface 202.

A hole 221, a hole 222, a hole 223, a hole 224, a hole 225, and a hole226 are formed in the body-side mount 200. The hole 221, the hole 222,the hole 223, the hole 224, the hole 225, and the hole 226 penetratefrom the lens mounting surface 201 to the mount securing surface 203.The hole 221, the hole 222, the hole 223, the hole 224, the hole 225,and the hole 226 are through-holes that penetrate from the lens mountingsurface 201 to the mount securing surface 203 in the z axis direction.

The front cover 300 has a front surface 301, a side portion 310 thatprotrudes in the positive z axis direction from the front surface 301and surrounds the securing section 110, and a flat surface portion 340that is parallel to the xy plane following the side portion 310. Theflat surface portion 340 has an opening 330. The opening 330 issubstantially circular in the xy plane. The diameter of the opening 330is larger than the outer diameter of the securing section 110 in the xyplane.

The front cover 300 has a front cover-side fastening portion 302 thatprotrudes from the side portion 310 toward the inside of the opening330. The front cover 300 has a front cover-side fastening portion 304that protrudes from the side portion 310 toward the inside of theopening 330. The front cover 300 has a front cover-side fasteningportion 306 that protrudes from the side portion 310 toward the insideof the opening 330. A hole 322 is formed in the front cover-sidefastening portion 302. A hole 324 is formed in the front cover-sidefastening portion 304. A hole 326 is formed in the front cover-sidefastening portion 306. The hole 322 is a through-hole. The hole 324 is athrough-hole. The hole 326 is a through-hole. The screw 232 is insertedthrough the hole 322. The screw 234 is inserted through the hole 324.The screw 236 is inserted through the hole 326. When assembling thebody-side mount 200, the front cover 300, and the body 100, the screw232 is inserted through the hole 322, the screw 234 is inserted throughthe hole 324, and the screw 236 is inserted through the hole 326.

The front cover-side fastening portion 302 is housed in the recessedportion 112. The front cover-side fastening portion 304 is housed in therecessed portion 114. The front cover-side fastening portion 306 ishoused in the recessed portion 116. The surface 332 of the frontcover-side fastening portion 302 is a surface that is on the oppositeside from the surface facing the floor portion 142 of the recessedportion 112, when the front cover-side fastening portion 302 is beinghoused in the recessed portion 112. The surface 334 of the frontcover-side fastening portion 304 is a surface that is on the oppositeside from the surface facing the floor portion 144 of the recessedportion 114, when the front cover-side fastening portion 304 is beinghoused in the recessed portion 114. The surface 336 of the frontcover-side fastening portion 306 is a surface that is on the oppositeside from the surface facing the floor portion 146 of the recessedportion 116, when the front cover-side fastening portion 306 is beinghoused in the recessed portion 116. A hole 322 is formed in the surface332 of the front cover-side fastening portion 302. A hole 324 is formedin the surface 334 of the front cover-side fastening portion 304. A hole326 is formed in the surface 336 of the front cover-side fasteningportion 306.

In a state where the front cover-side fastening portion 302 is housed inthe recessed portion 112, the front cover-side fastening portion 304 ishoused in the recessed portion 114, and the front cover-side fasteningportion 306 is housed in the recessed portion 116, the first surface150, the surface 332, the surface 334, and the surface 336 form a flatsurface. Specifically, the top surface 151 of the convex portion 111 ofthe body 100, the top surface 153 of the convex portion 113 of the body100, the top surface 155 of the convex portion 115 of the body 100, thesurface 332 of the front cover-side fastening portion 302, the surface334 of the front cover-side fastening portion 304, and the surface 336of the front cover-side fastening portion 306 form a flat surface thatis parallel to the xy plane. In other words, the flat surface includingthe top surface 151, the top surface 153, the top surface 155, thesurface 332, the surface 334, and the surface 336 is parallel to the xyplane. In a state where the body-side mount 200 is in contact with theflat surface formed by the first surface 150, the surface 332, thesurface 334, and the surface 336, the front cover 300 and the body 100are fastened thereto by the screw 232, the screw 234, and the screw 236.Specifically, in a state where the mount securing surface 203 of thebody-side mount 200 is in contact with the flat surface formed by thefirst surface 150, the surface 332, the surface 334, and the surface336, the body-side mount 200, the front cover 300, and the body 100 arefastened together.

In a state where the front cover-side fastening portion 302 is housed inthe recessed portion 112, the front cover-side fastening portion 304 ishoused in the recessed portion 114, and the front cover-side fasteningportion 306 is housed in the recessed portion 116, the hole 322 ispositionally fixed at the position of the hole 122 in the xy plane, thehole 324 is positionally fixed at the position of the hole 124 in the xyplane, and the hole 326 is positionally fixed at the position of thehole 126 in the xy plane. The state where the front cover-side fasteningportion 302 is housed in the recessed portion 112, the front cover-sidefastening portion 304 is housed in the recessed portion 114, and thefront cover-side fastening portion 306 is housed in the recessed portion116 may be referred to as a state in which the front cover 300 ispositionally fixed relative to the body 100.

In the body-side mount 200, the hole 221 is positioned at a positioncorresponding to the hole 121. The hole 222 is positioned at a positioncorresponding to the hole 122. The hole 223 is positioned at a positioncorresponding to the hole 123. The hole 224 is positioned at a positioncorresponding to the hole 124. The hole 225 is positioned at a positioncorresponding to the hole 125. The hole 226 is positioned at a positioncorresponding to the hole 126.

For example, when the body-side mount 200 and the body 100 arepositionally fixed such that the hole 221 is positionally fixed at theposition of the hole 121 in the xy plane and the hole 224 ispositionally fixed at the position of the hole 124 in the xy plane, thehole 222 is positionally fixed at the position of the hole 122 in the xyplane, the hole 223 is positionally fixed at the position of the hole123 in the xy plane, the hole 225 is positionally fixed at the positionof the hole 125 in the xy plane, and the hole 226 is positionally fixedat the position of the hole 126 in the xy plane. The state where thehole 221, the hole 222, the hole 223, the hole 224, the hole 225, andthe hole 226 of the body-side mount 200 are respectively positionallyfixed at the positions of the hole 121, the hole 122, the hole 123, thehole 124, the hole 125, and the hole 126 may be referred to as a statein which the body-side mount 200 is positionally fixed relative to thebody 100.

In a state where the front cover 300 is positionally fixed relative tothe body 100 and the body-side mount 200 is positionally fixed relativeto the body 100, the screw 231 is inserted through the hole 221 and thehole 121, the screw 233 is inserted through the hole 223 and the hole123, the screw 235 is inserted through the hole 225 and the hole 125,and the body-side mount 200 and body 100 are attached directly to eachother by the screw 231, the screw 233, and the screw 235.

Furthermore, in the state where the front cover 300 is positionallyfixed relative to the body 100 and the body-side mount 200 ispositionally fixed relative to the body 100, the screw 232 is insertedthrough the hole 222, the hole 322, and the hole 122, the screw 234 isinserted through the hole 224, the hole 324, and the hole 124, the screw236 is inserted through the hole 226, the hole 326, and the hole 126,and body-side mount 200, the front cover 300, and the body 100 arefastened by the screw 232, the screw 234, and the screw 236. In a statewhere the front cover-side fastening portion 302, the front cover-sidefastening portion 304, and the front cover-side fastening portion 306are sandwiched by the body-side mount 200 and the body 100 in the z axisdirection in this manner, the body-side mount 200 and the body 100 arefastened together by the screw 232, the screw 234, and the screw 236. Inthe state where the front cover 300 is sandwiched by the body-side mount200 and the body 100 in a prescribed direction in this manner, thebody-side mount 200 and the body 100 are fastened together by thescrews. Accordingly, the front cover 300 is secured in a state of beingsandwiched by the body-side mount 200 and the body 100 in the prescribeddirection.

In the xy plane, the hole 221, the hole 222, the hole 223, the hole 224,the hole 225, and the hole 226 are positioned in the same circle.Specifically, in the xy plane, the hole 221, the hole 222, the hole 223,the hole 224, the hole 225, and the hole 226 are formed at positionsevery 60 degrees around the optical axis. The hole 221, the hole 223,and the hole 225 are positioned at the vertices of an equilateraltriangle. The hole 222, the hole 224, and the hole 226 are positioned atthe vertices of an equilateral triangle.

In this way, the body-side mount 200 is fastened in its entirety to thebody 100 at six points in the same circle. Specifically, the body-sidemount 200 is directly fastened to the body 100 at three points in thesame circle, and is also fastened to the body 100 with the front cover300 interposed therebetween at another three points in the same circle.The front cover 300 is fastened to the body-side mount 200 at threepoints, and is also fastened to the body 100 at the same three points.

In this way, the front cover 300 and the body 100 are secured to thebody-side mount 200, and therefore it is difficult for stress to betransferred from the front cover 300 to the body 100. For example, thebody-side mount 200, the front cover 300, and the body 100 are fastenedtogether, and therefore it is difficult for twisting stress to occur inthe body 100. Therefore, the body 100 is more difficult to deform whenstress is placed on the front cover 300. Accordingly, it is possible torestrict the reduction in the positioning accuracy of the imaging unit160, which is an example of a light receiving unit.

The front cover-side fastening portion 302, the front cover-sidefastening portion 304, and the front cover-side fastening portion 306 ofthe front cover 300 are examples of exterior-side fastening portionsthat are fastened to the body-side mount 200. The screw 232, the screw234, and the screw 236 are examples of first fastening members thatfasten together the body-side mount 200, the fastening portion of thefront cover 300, and the body 100. The screw 231, the screw 233, and thescrew 235 are examples of second fastening members that fasten the body100 to the body-side mount 200 without fastening the body 100 to thefront cover 300.

The hole 122 positioned in the floor portion of the recessed portion 112in the securing section 110 is an example of a first fastening portionthat fastens together the body-side mount 200 and the front cover 300using a screw. The hole 121 positioned in the convex portion 111 of thesecuring section 110 is an example of a second fastening portion forfastening to the body-side mount 200 without fastening to the frontcover 300. In other words, in a state where a first fastening portion ofthe body 100 is positioned at the bottom of a recessed portion housingan external fastening portion and the external fastening portion ishoused in the recessed portion, the body 100 is fastened together withthe body-side mount 200 by the screws.

As described above, in a state where the front cover-side fasteningportion 302, the front cover-side fastening portion 304, and the frontcover-side fastening portion 306 are respectively housed in the recessedportion 112, the recessed portion 114, and the recessed portion 116, thefirst surface 150 of the body 100 and the surface 332, the surface 334,and the surface 336 of the front cover 300 form a flat surfacecontacting the mount securing surface 203 of the body-side mount 200.However, the first surface 150 of the body 100 and the surface 332, thesurface 334, and the surface 336 of the front cover 300 need not form aflat surface. The surface shape of the surface formed by the firstsurface 150 of the body 100 and the surface 332, the surface 334, andthe surface 336 of the front cover 300 may have a shape corresponding tothe surface shape of the mount securing surface 203 of the body-sidemount 200. A portion of each of the front cover-side fastening portion302, the front cover-side fastening portion 304, and the frontcover-side fastening portion 306 may be housed in the correspondingrecessed portion 112, recessed portion 114, and recessed portion 116. Ina state where a portion of each of the front cover-side fasteningportion 302, the front cover-side fastening portion 304, and the frontcover-side fastening portion 306 is housed in the corresponding recessedportion 112, recessed portion 114, and recessed portion 116, the surface332 of the front cover-side fastening portion 302, the surface 334 ofthe front cover-side fastening portion 304, and the surface 336 of thefront cover-side fastening portion 306 may protrude in the positive zaxis direction from the first surface 150. Accordingly, at least aportion of each of the front cover-side fastening portion 302, the frontcover-side fastening portion 304, and the front cover-side fasteningportion 306 may be housed in the corresponding recessed portion 112,recessed portion 114, and recessed portion 116.

If the front cover 300 is at a location near the location on the body100 where the body-side mount 200 is secured, the front cover 300 may besecured to the body 100. For example, a location of the front cover 300that protrudes in the positive z axis direction beyond the front surface301 may be secured to a location on the body 100 that protrudes in thepositive z axis direction beyond the front surface 301. For example, theside portion 310 of the front cover 300 may be secured to the securingsection 110. As another example, if the front cover 300 has a surfacethat is substantially parallel to a secure surface that is secured tothe body 100 by the body-side mount 200, e.g. the first surface 150, andthat is positioned farther on the optical axis side than the frontsurface 301 in the xy plane, this surface may be secured to the body100. For example, the surface 308 of the front cover 300 may be fastenedto the surface 158 of the front surface 101.

If the front cover 300 is distanced from the location on the body 100where the body-side mount 200 is secured by less than or equal to apredetermined distance, the front surface 301 of the front cover 300 andthe body 100 may be secured. In this case, the position where the frontcover 300 and the body 100 are secured is preferably within a range thatforms a rectangle surrounding and in contact with the outer ring of thebody-side mount 200. Specifically, when the distance from the opticalaxis to the outer ring of the body-side mount 200 in the xy plane is r,the distance between the optical axis and the position at which thefront cover 300 and the body 100 are secured is preferably less than orequal to a value obtained as the product of r and the square root of 2.Also, if the side portion 310 of the front cover 300 is secured to thebody 100, the distance between the optical axis and the position atwhich the front cover 300 and the body 100 are secured is preferablyless than or equal to a value obtained as the product of r and thesquare root of 2.

The following is a basic description of the mounting mechanism formounting an interchangeable lens on the body-side mount 200. Theinterchangeable lens is mounted on the body-side mount 200 by a bayonetmechanism. The body-side mount 200 has a claw portion 281 and a clawportion 282. The claw portion 281 and the claw portion 282 are used formounting the interchangeable lens on the body-side mount 200. Thebody-side mount 200 includes three claw portions used for mounting theinterchangeable lens on the mounting surface 201. The claw portion 281and the claw portion 282 shown in FIG. 3 are two of the three clawportions of the body-side mount 200. The three claw portions of thebody-side mount 200 may be simply referred to as the claw portions.

The claw portion 281 and the claw portion 282 are provided on the sidesurface 204 of the body-side mount 200. The claw portion 281 and theclaw portion 282 protrude toward the inside of the opening 230 of thebody-side mount 200. A stepped portion 284 is formed in the side surface204 of the body-side mount 200 between the claw portion 281 and the clawportion 282 that is adjacent to the claw portion 281. The steppedportion 284 is a portion in the side surface 204 that does not protrudetoward the inside of the opening 230. Stepped portions that are the sameas the stepped portion 284 are formed between adjacent claw portions inthe side surface 204 of the body-side mount 200. Accordingly, threestepped portions are formed in the side surface 204 of the body-sidemount 200.

The interchangeable lens includes a lens-side mount for mounting on thebody-side mount 200. The lens-side mount of the interchangeable lensincludes three claw portions for mounting the interchangeable lens onthe body-side mount 200. The three claw portions of the lens-side mountof the interchangeable lens may be referred to as lens-side clawportions.

When mounting the interchangeable lens on the body-side mount 200, in astate where an attachment mark 394 provided on the front cover 300 isaligned around the z axis with an attachment mark provided on theinterchangeable lens, the interchangeable lens is inserted into theopening 230 of the body-side mount 200. In a state where the attachmentmark of the interchangeable lens and the attachment mark 394 arealigned, the lens-side claw portions of the interchangeable lens arepositioned at the stepped portions 284 of the body-side mount 200 in thexy plane.

Accordingly, in a state where the attachment mark of the interchangeablelens and the attachment mark 394 are aligned, when the interchangeablelens is inserted into the opening 230 of the body-side mount 200, thelens-side claw portions of the interchangeable lens pass through thestepped portions 284 of the body-side mount 200 in the negative z axisdirection to be inserted up to a position behind the corresponding clawportions. In this state, when the interchangeable lens is rotated aroundthe z axis, the three lens-side claw portions of the interchangeablelens enter behind the corresponding claw portions of the body-side mount200. The rotation of the interchangeable lens around the z axis islimited by a portion of the camera mount of the interchangeable lenscontacting the end portions 288 of the claw portions 281.

A flat spring is secured on the mounting surface 201 of the body-sidemount 200 to realize firm contact between the mounting surface 201 andthe mounting surface of the lens-side mount, as a result of beingsandwiched between the mount securing surface 203 and the first surface150 of the body 100. The flat spring has a protruding portion thatprotrudes in the negative z axis direction beyond the surface of themount securing surface 203 on which the flat spring is secured, and thelens-side mount of the interchangeable lens is biased in the negative zaxis direction by the protruding portion of the flat spring. As aresult, the interchangeable lens is restricted from moving in the z axisdirection relative to the body-side mount 200. The mounting surface ofthe lens-side mount of the interchangeable lens is in firm contact whentouching the mounting surface 201 of the body-side mount 200. In thisway, the interchangeable lens is mounted on the body-side mount 200 bythe bayonet mechanism.

The mounting surface 201 is a reference surface for determining a flangeback. The flange back is determined according to the distance betweenthe mounting surface 201 and the imaging surface of the imaging elementin the z axis direction.

A pin hole 290 is formed penetrating through the body-side mount 200from the mounting surface 201 of the body-side mount 200 to the mountsecuring surface 203. A lock pin for limiting the rotation of theinterchangeable lens relative to the body-side mount 200 is insertedthrough the pin hole 290. The lock pin is biased in the positive z axisdirection by the bias force of a spring. The lock pin protrudes from themounting surface 201 in the positive z axis direction into the pin hole290 when the body-side mount 200 is secured to the body 100. A pin holeis formed in the lens-side mount of the interchangeable lens. A portionof the lock pin protruding in the positive z axis direction from themounting surface 201 is inserted into the pin hole of theinterchangeable lens. By inserting the portion of the lock pin into thepin hole of the interchangeable lens, the rotation of theinterchangeable lens mounted on the body-side mount 200 around the zaxis is limited.

An opening 390 for exposing a lock release button to the outside isformed in the front cover 300. When the lock release button is pressed,the lock pin moves in conjunction with the movement of the lock releasebutton to be displaced in the negative z axis direction against the biasforce of the spring. When the entire lock pin is displaced beyond themounting surface 201 in the negative z axis direction, it is possiblefor the interchangeable lens to rotate around the x axis.

When the interchangeable lens is mounted on the body-side mount 200, thelight that has passed through the interchangeable lens can pass furtherinward than the claw portions of the body-side mount 200. The clawportions of the body-side mount 200 determine an opening diameter of themount. The opening diameter of the mount is determined to be a valuethat is twice the distance between a claw portion and the z axis in thexy plane.

The attachment mark 394 may be colored a different color than the coloraround the attachment mark 394 in the front cover 300. The attachmentmark 394 is provided on the front cover 300. However, a similarattachment mark may be provided on the body-side mount 200. For example,an attachment mark may be formed on the mounting surface 201 of thebody-side mount 200. The attachment mark 394 is formed at a locationthat is depressed beyond the mounting surface 201 of the body-side mount200.

In the above example, the hole 221, the hole 222, the hole 223, the hole224, the hole 225, and the hole 226 of the body-side mount 200 arepositioned in the same circle in the xy plane. The hole 222, the hole224, and the hole 226 may be arranged in the same circle. The hole 221,the hole 223, and the hole 225 may be positioned in the same circle.Here, the center of the circle passing through the hole 221, the hole223, and the hole 225 preferably matches the center of the circlepassing through the hole 222, the hole 224, and the hole 226. As anexample, the diameter of the circle passing through the hole 221, thehole 223, and the hole 225 and the diameter of the circle passingthrough the hole 222, the hole 224, and the hole 226 may be the same ormay be different. For example, the diameter of the circle passingthrough the centers of each of the hole 221, the hole 223, and the hole225 and the diameter of the circle passing through the centers of eachof the hole 222, the hole 224, and the hole 226 may be the same or maybe different. If the diameter of the circle passing through the hole221, the hole 223, and the hole 225 is different from the diameter ofthe circle passing through the hole 222, the hole 224, and the hole 226,the diameter of the circle passing through the hole 222, the hole 224,and the hole 226 may be greater than the diameter of the circle passingthrough the hole 221, the hole 223, and the hole 225. It should be notedthat the positional relationship of the hole 221, the hole 222, the hole223, the hole 224, the hole 225, and the hole 226 is not limited to thisexample. As another example, the hole 221, the hole 222, the hole 223,the hole 224, the hole 225, and the hole 226 may be positioned at anyposition in the mounting surface 201, as long as these holes are formedin the mounting surface 201.

The hole 322 need not be a through-hole. In this case, the hole 322 maybe a female thread. The hole 322 may be a female thread that penetratesthrough the front cover-side fastening portion 302. The hole 324 neednot be a through-hole. In this case, the hole 324 may be a femalethread. The hole 324 may be a female thread that penetrates through thefront cover-side fastening portion 304. The hole 326 need not be athrough-hole. In this case, the hole 326 may be a female thread. Thehole 326 may be a female thread that penetrates through the frontcover-side fastening portion 306. If the hole 322 is not a through-hole,the body 100 need not include the hole 122. If the hole 324 is not athrough-hole, the body 100 need not include the hole 124. If the hole326 is not a through-hole, the body 100 need not include the hole 126.

If the hole 322 is a female thread, the body-side mount 200 and thefront cover-side fastening portion 302 may be fastened by the screw 232.In this case the front cover-side fastening portion 302 and the body 100need not be fastened. If the hole 324 is a female thread, the body-sidemount 200 and the front cover-side fastening portion 304 may be fastenedby the screw 234. In this case the front cover-side fastening portion304 and the body 100 need not be fastened. If the hole 326 is a femalethread, the body-side mount 200 and the front cover-side fasteningportion 306 may be fastened by the screw 236. In this case the frontcover-side fastening portion 306 and the body 100 need not be fastened.

The hole 121, the hole 122, the hole 123, the hole 124, the hole 125,and the hole 126 need not be through-holes. In this case, the hole 121,the hole 122, the hole 123, the hole 124, the hole 125, and the hole 126may be female threads.

In the imaging device 10, the exterior of the imaging device 10 isformed by the three covers that are the front cover 300, the top cover400, and the back cover 500. However, the exterior of the imaging device10 may be formed by two covers. If the exterior of the imaging device 10is formed by two covers, the body 100 is covered by these two covers.The exterior of the imaging device 10 may be formed by four covers. Ifthe exterior of the imaging device 10 is formed by four covers, the body100 is covered by these four covers. The exterior of the imaging device10 may be formed by two or more covers.

As described above, the body-side mount 200 is formed of metal and thefront cover 300 is formed of resin. However, the material forming thebody-side mount 200 is not limited to metal, as long as the materialused results in the stiffness of the body-side mount 200 being greaterthan the stiffness of the front cover 300. For example, the body-sidemount 200 may be formed of resin. In the same manner, the materialforming the front cover 300 is not limited to resin. For example, thefront cover 300 may be formed of metal.

FIG. 4 is an exploded perspective view of the imaging device 10. FIG. 4shows an electronic device substrate 820, a power supply unit 840, andthe imaging unit 160, along with the body 100, the front cover 300, thetop cover 400, and the back cover 500.

The imaging unit 160 includes an imaging element that receives lightfrom a subject. The imaging unit 160 is fastened and secured to thebracket 170. In this way, the imaging unit 160 is secured to the body100 via the bracket 170.

An electronic component for processing a signal output from the imagingelement of the imaging unit 160 is implemented on the electronic devicesubstrate 820. The imaging unit 160 and the electronic device substrate820 are connected via a circuit board such as a flexible print substrateinterposed therebetween.

The power supply unit 840 supplies power to each component of theimaging device 10. The power from the power supply unit 840 is suppliedto the electronic device substrate 820 via the circuit board such as theflexible print substrate. The power from the power supply unit 840 maybe supplied to the imaging unit 160 via the electronic device substrate820.

The substrate cover 800 is secured to the front cover 300. Theelectronic device substrate 820 is secured to the substrate cover 800.

As described above, the front cover 300 is rigidly connected by screwsto the securing section 110 of the body 100. The front cover 300 is notrigidly connected to the body 100 at any location other than thesecuring section 110. For example, when stress is placed on the frontcover 300, the stress transferred to the back surface 102 of the body100 via the substrate cover 800, the electronic device substrate 820,and the circuit board is much less than the stress transferred to thesecuring section 110 of the front surface 101. The securing section 110of the body 100 has the body-side mount 200 secured thereto, andtherefore the securing section 110 has higher stiffness than the backsurface 102. Accordingly, even when stress is transferred to thesecuring section 110, the body 100 does not significantly deform.Therefore, it is possible to significantly reduce the effect on thepositioning accuracy of the imaging unit 160 caused by the stress placedon the front cover 300.

FIG. 5 is a cross-sectional view obtained by cutting the imaging device10 in the xy plane. FIG. 5 shows the front cover 300, the top cover 400,and the back cover 500.

The front cover 300 and the top cover 400 are connected by a spigotstructure. At the connecting section 401 connecting the front cover 300and the top cover 400, the top cover 400 includes a convex portion 450that protrudes in the positive z axis direction from the surface facingthe front cover 300. The front cover 300 includes a recessed portion 350that is recessed in the positive z axis direction from the surfacefacing the top cover 400. The front cover 300 and the top cover 400 areconnected by engagement between the recessed portion 350 of the frontcover 300 and the convex portion 450 of the top cover 400.

The front cover 300 and the back cover 500 are connected by a spigotstructure. At the connecting section 402 connecting the front cover 300and the back cover 500, the top cover 400 includes a convex portion 460that protrudes in the negative z axis direction from the surface facingthe back cover 500. The back cover 500 includes a recessed portion 560that is depressed in the negative z axis direction from the surfacefacing the top cover 400. The back cover 500 and the top cover 400 areconnected by engagement between the recessed portion 560 of the backcover 500 and the convex portion 460 of the top cover 400.

In a similar manner, at the connecting section 403 connecting the frontcover 300 and the top cover 400, the front cover 300 and the top cover400 are connected by a spigot structure. In a similar manner, at theconnecting section 404 connecting the back cover 500 and the top cover400, the back cover 500 and the top cover 400 are connected by a spigotstructure.

Although not shown in FIG. 5, as described above, at the contact surfacebetween the front cover 300 and the back cover 500, the front cover 300and the back cover 500 are connected by a spigot structure. In this way,the front cover 300 and the top cover 400 are connected by a spigotstructure along the contact surface between the front cover 300 and thetop cover 400. Furthermore, the top cover 400 and the back cover 500 areconnected by a spigot structure along the contact surface between thetop cover 400 and the back cover 500. The front cover 300 and the backcover 500 are connected by a spigot structure along the contact surfacebetween the front cover 300 and the back cover 500. In this way, thefront cover 300, the top cover 400, and the back cover 500 are connectedby spigot structures at the contact surfaces with the other covers.Therefore, when stress is placed on any one of the front cover 300, thetop cover 400, and the back cover 500, it is possible to restrictshifting in the direction parallel to the contact surfaces with theother covers.

The exterior portion formed by the front cover 300, the top cover 400,and the back cover 500 has a monocoque structure for receiving stress.As described above, the front cover 300, the top cover 400, and the backcover 500 have contact surfaces that are connected to each other with aspigot structure, and therefore the monocoque structure is preserveddespite forming the exterior with a plurality of components such as thefront cover 300, the top cover 400, and the back cover 500.

The weight of the body 100 is preferably approximately the same as theweight of other components of the imaging device 10. By making theweight of the body 100 be approximately the same as the weight of theother components of the imaging device 10, it is possible to attenuatevibration caused by the movement of the shutter, mirror, or the like inthe body 100. The error between the weight of the body 100 and theweight of the other components is preferably no greater than 5%. If theweight of the body 100 differs from the weight of the other components,the body 100 is preferably heavier than the other components.

FIG. 6 is an exploded perspective view schematically showing assembly ofthe front cover 300, the top cover 400, the back cover 500, and thesuspension ring 600. FIG. 7 is an exploded perspective view showing astate in which the suspension ring 600 is positionally fixed to the topcover 400.

The back cover 500 includes a screw hole 511, a screw hole 512, a screwhole 513, a screw hole 514, and a screw hole 515. The screw hole 511,the screw hole 512, the screw hole 513, the screw hole 514, and thescrew hole 515 are each formed along the z axis direction. The top cover400 includes a screw hole 413, a screw hole 414, and a screw hole 415.The screw hole 413, the screw hole 414, and the screw hole 415 are eachformed along the z axis direction. The front cover 300 includes a screwhole 311 and a screw hole 312. The screw hole 311 and the screw hole 312are each formed along the z axis direction.

The top cover 400 and the back cover 500 are fastened by screws in astate where the screw hole 413 and the screw hole 513 are positionallyfixed, the screw hole 414 and the screw hole 514 are positionally fixed,and the screw hole 415 and the screw hole 515 are positionally fixed.The front cover 300 and the back cover 500 are fastened by screws in astate where the screw hole 311 and the screw hole 511 are positionallyfixed.

The suspension ring 600 is secured to the front cover 300 and the backcover 500. The suspension ring 600 is formed of metal. The suspensionring 600 is a metal fitting for attaching a hanging strap to the imagingdevice 10.

The suspension ring 600 includes a front-side fastening portion 610, aback-side fastening portion 620, a connecting portion 630 that connectsthe front-side fastening portion 610 and the back-side fastening portion620, and a ring portion 640. The suspension ring 600 is secured in astate where the ring portion 640 protrudes from the opening 480 formedin the top cover 400. A strap can be attached to the ring portion 640.The strap may be attached to the ring portion 640 via a metal fittingfor attaching a triangular ring or the like to which the strap isattached.

The front-side fastening portion 610 is positioned farther in thepositive z axis direction than the back-side fastening portion 620. Thefront-side fastening portion 610 has a surface that is parallel to thexy plane and extends in the positive y axis direction from theconnecting portion 630. The back-side fastening portion 620 has asurface that is parallel to the xy plane and extends in the negative yaxis direction from the connecting portion 630. The connecting portion630 extends in the z axis direction. The connecting portion 630 connectsa top portion of the front-side fastening portion 610 to a bottomportion of the back-side fastening portion 620.

The front-side fastening portion 610 has a screw hole 612 formed alongthe z axis direction. The back-side fastening portion 620 has a screwhole 622 formed along the z axis direction.

The front cover 300 and the suspension ring 600 are fastened by a screwin a state where the screw hole 312 and the screw hole 612 arepositionally fixed. The suspension ring 600 and the back cover 500 arefastened by a screw in a state where the screw hole 622 and the screwhole 512 are positionally fixed. In this way, the front cover 300 andthe back cover 500 are secured via the suspension ring 600.

As described above, the top cover 400 and the back cover 500 have acontact surface that is substantially orthogonal to the z axisdirection. The top cover 400 and the back cover 500 are fastened byscrews with a fastening axis along the z axis direction. In the samemanner, the front cover 300 and the back cover 500 have a contactsurface that is substantially orthogonal to the z axis direction. Thefront cover 300 and the back cover 500 are fastened by screws with afastening axis along the z axis direction. Therefore, it is possible tofurther restrict sliding of the contact surfaces. Although not shown inFIGS. 6 and 7, the front cover 300 and the top cover 400 are fastened byscrews with a fastening axis along the z axis direction.

As described above, the front cover 300, the top cover 400, and the backcover 500 have fastening axes orthogonal to the contact surfacestherebetween, and therefore the stress applied to any one of thesecovers can be transferred efficiently to the other covers. Therefore, itis possible to preserve the monocoque structure despite forming theexterior portion with a plurality of components such as the front cover300, the top cover 400, and the back cover 500. Accordingly, it ispossible to diffuse the stress placed on any one of the front cover 300,the top cover 400, and the back cover 500 to other covers. For example,when stress is placed on the back cover 500 from the outside, the stressplaced on the back cover 500 from the outside can be diffused to thefront cover 300 and the top cover 400. Accordingly, it is possible todecrease the stress value received by the back cover 500. In this way,it is possible to restrict the focusing of stress on a single one of thefront cover 300, the top cover 400, and the back cover 500, andtherefore it is possible to restrict damage to each cover. Accordingly,it is possible to increase the shock resistance. Furthermore, it ispossible to omit support members, and therefore the imaging device 10can be made lighter weight. Yet further, even if there is a significanterror in the dimensions of the front cover 300, the top cover 400, andthe back cover 500, it is possible to remove gaps between the covers atthe contact surfaces therebetween. Therefore, it is possible to increasethe quality of the outside appearance of the imaging device 10.

One end of the suspension ring 600 is secured to the front cover 300,and the other end of the suspension ring 600 is secured to the backcover 500. Stress is placed on the suspension ring 600 by the attachedstrap, but since the suspension ring 600 is secured to both the frontcover 300 and the back cover 500, it is possible to diffuse the stressplaced on the suspension ring 600 to the front cover 300 and the backcover 500.

The screw holes for fastening the front cover 300, the top cover 400,and the back cover 500 to each other are provided at the corners whenviewing the entire outside appearance of the imaging device 10. Forexample, the imaging device 10 has an overall box shape, and the screwhole 511 and the screw hole 512 are provided in the back cover 500 atcorners of this box shape. Therefore, the stress can be diffused acrosstwo edges and the number of fastening members such as the screws can bereduced. The screw hole 513 and the screw hole 514 are provided at thecorners of the finder opening 590 of the top cover 400. In the top cover400, the screw hole 413 and the screw hole 414 are positioned near theaccessory shoe 470. The screw hole 413 and the screw hole 414 arearranged at positions enabling stress to be diffused when stress isplaced on the accessory shoe 470 due to mounting of an externalaccessory. For example, the screw hole 413 and the screw hole 414 arearranged at locations where the stress placed on the accessory shoe 470from an external accessory is greater than a predetermined value. Asanother example, the screw hole 413 and the screw hole 414 are arrangednear a stress line caused by an external accessory.

FIG. 8 is an exploded perspective view schematically showing theassembly of the front cover 300, the back cover 500, and a tripod base700. FIG. 9 is a cross-sectional view of a yz cross sectionschematically showing a state in which the tripod base 700 is assembledwith the front cover 300 and the back cover 500.

The front cover 300 includes a rib 381 and a rib 382 on a loadingsurface 370 on which a portion of the tripod base 700 is loaded. The rib381 and the rib 382 are distanced from each other in the x axisdirection. The rib 381 and the rib 382 extend in a direction toward theposition of the securing section 110. A portion of the tripod base 700is housed between the rib 381 and the rib 382. The front cover 300further includes a rib 383 and a rib 384 that extend toward the securingsection 110. The rib 383 and the rib 384 are positioned between the rib381 and the rib 382 in the x axis direction. The rib 383 and the rib 384are positioned between the securing section 110 and the position wherethe tripod base 700 is secured in the z axis direction.

A screw hole 371 and a screw hole 372 are formed in the loading surface370. A notched portion 375 having a semicircular shape in the xz planeis formed in the loading surface 370.

In the back cover 500, a screw hole 573 and a screw hole 574 are formedin a loading surface 570 on which a portion of the tripod base 700 isloaded. The loading surface 570 includes a rib 581 and a rib 582. Therib 581 and the rib 582 extend in the z axis direction. When the frontcover 300 and the back cover 500 are aligned, the rib 581 is adjacent tothe rib 381 at a position on the negative x axis direction side of therib 381. The rib 582 is adjacent to the rib 382 at a position on thepositive x axis direction side of the rib 382. The height to which therib 381 and the rib 382 protrude from the loading surface 370 ispreferably greater than the height to which the rib 581 and the rib 582protrude from the loading surface 570.

A notched portion 575 having a semicircular shape in the xz plane isformed in the loading surface 570. When the front cover 300 and the backcover 500 are aligned, the notched portion 375 and the notched portion575 form a housing opening 585 that houses the attaching portion 770 forattaching the tripod base 700 to a tripod.

A screw hole 701, a screw hole 702, a screw hole 703, and a screw hole704 are formed in the tripod base 700. The screw hole 701 corresponds tothe screw hole 371, the screw hole 702 corresponds to the screw hole372, the screw hole 703 corresponds to the screw hole 573, and the screwhole 704 corresponds to the screw hole 574. Specifically, in a statewhere the tripod base 700 is sandwiched between the rib 381 and the rib382 and loaded on the loading surface 370, the screw hole 701 ispositionally fixed at the position of the screw hole 371 and the screwhole 702 is positionally fixed at the position of the screw hole 372.Furthermore, in a state where the front cover 300 and the back cover 500are positionally fixed, the screw hole 703 is positionally fixed at theposition of the screw hole 573 and the screw hole 704 is positionallyfixed at the position of the screw hole 574. In a state where the frontcover 300 and the back cover 500 are aligned, the tripod base 700 isfastened to the front cover 300 by inserting screws through the screwhole 701 and the screw hole 702. Furthermore, the tripod base 700 isfastened to the back cover 500 by inserting screws through the screwhole 703 and the screw hole 704.

The rib 381 and the rib 382 protrude in the negative z axis directionbeyond the edge of the loading surface 370 positioned on the negative zaxis direction side. The rib 581 and the rib 582 protrude in thepositive z axis direction beyond the edge of the loading surface 570positioned on the positive z axis direction side. Accordingly, theposition at which the front cover 300 and the back cover 500 areconnected can be restricted from being displaced in a direction awayfrom the tripod base 700.

In this way, one end of the tripod base 700 is secured to the frontcover 300 and the other end of the tripod base 700 is secured to theback cover 500. Stress is placed on the tripod base 700 by the attachedtripod, but since the tripod base 700 is fastened to both the frontcover 300 and the back cover 500, it is possible to diffuse the stressplaced on the tripod base 700 to the front cover 300 and the back cover500.

The front cover 300 includes the rib 381, the rib 382, the rib 383, andthe rib 384, and therefore deformation of the front cover 300 caused bystressed placed thereon via the tripod base 700 can be restricted. Inparticular, the rib 381, the rib 382, the rib 383, and the rib 384extend from a position near where the tripod base 700 is secured to aposition near the securing section 110. Therefore, it is possible torestrict localized stress from being focused between the securingsection 110 and the position where the tripod base 700 is secured andcausing localized bending of the front cover 300.

The length of the tripod base 700 in the z axis direction is greaterthan the length of the tripod base 700 in the x axis direction. It orderto avoid the focusing of stress placed on the tripod base 700, it ismore preferable for the length of the tripod base 700 in the z axisdirection to be longer. The tripod base 700 more preferably extends to aposition closer to the securing section 110.

When forming the front cover 300 using resin molding, the rib 381, therib 382, the rib 383, and the rib 384 are preferably formed in a mannerto not include welding. In particular, it is preferable that weld linesdo not intersect with the extension direction of the rib 381, the rib382, the rib 383, and the rib 384. A gate is preferably arranged suchthat the resin flows parallel to the extension direction of the rib 381,the rib 382, the rib 383, and the rib 384. A gate faucet is preferablyarranged in a mold that is continuous from the securing section 110 tothe rib 381, the rib 382, the rib 383, and the rib 384. A guide wall maybe formed to guide the resin to form the rib 381, the rib 382, the rib383, and the rib 384.

FIG. 10 is a perspective view of a portion of the back cover 500. FIG.10 particularly shows the floor portion and the opening 520 of the backcover 500. The opening 520 is an opening for exposing the displaysurface of a display apparatus to the outside form the imaging device10.

The back cover 500 includes a rib 540 that is positioned below theopening 520. The rib 540 extends in the x axis direction. The length ofthe rib 540 in the x axis direction is greater than the length of theopening 520 in the x axis direction. The rib 540 extends in the negativex axis direction beyond the end portion of the opening 520 on thenegative x axis direction side. The rib 540 extends to the fasteningportion 521 in which a screw hole 511 is formed.

A support portion 551 and a support portion 552 supporting the displayapparatus are provided on the rib 540. The display apparatus is incontact with and supported from below by the support portion 551 and thesupport portion 552.

The rib 581 and the rib 582 extend to the rib 540. Therefore, it ispossible to restrict the localized focusing of stress in the loadingsurface 570.

FIG. 11 is an exploded perspective view schematically showing anotherassembly example of the tripod base assembly. In this assembly example,a tripod base attaching member 1180 securing a tripod base 1170 isfastened together with the body-side mount 200 and a body 1100.

The body-side mount 200 has the same structure as the body-side mount200 described in relation to FIGS. 1 to 10. The body 1100 is formed ofresin, in the same manner as the body 100. The tripod base attachingmember 1180 and the tripod base 1170 are formed of metal. The tripodbase 1170 is a metal fitting for attaching a tripod.

The tripod base attaching member 1180 includes a securing section 1150and a tripod base attaching portion 1140. The tripod base attachingmember 1180 has an overall L shape when cut in the xy plane. When thetripod base attaching member 1180 and the body 1100 are aligned, thetripod base attaching portion 1140 is positioned below the body 1100.

Four female threads that are a female thread 1141, a female thread 1142,a female thread 1143, and a female thread1144 are formed in the tripodbase attaching portion 1140. Four through-holes including a hole 1172, ahole 1173, and a hole 1174 are formed in the tripod base 1170. When thetripod base 1170 is aligned with the tripod base attaching portion 1140,the four screw holes formed in the tripod base attaching portion 1140are positionally fixed at the positions of the four holes formed in thetripod base 1170, in a one-to-one manner. For example, the female thread1142 is positionally fixed at the position of the hole 1172, the femalethread 1143 is positionally fixed at the position of the hole 1173, andthe female thread 1144 is positionally fixed at the position of the hole1174. In this state, the screw 1181 is inserted through the femalethread 1141, the screw 1182 is inserted through the female thread 1142,the screw 1183 is inserted through the female thread 1143, and the screw1184 is inserted through the female thread 1144, thereby fastening thetripod base 1170 to the tripod base attaching portion 1140.

A female thread 1121, a female thread 1122, a female thread 1123, afemale thread 1124, a female thread 1125, and a female thread 1126 areformed in the securing section 1110 of the body 1100. A hole 1151, ahole 1152, a hole 1153, a hole 1154, a hole 1155, and a hole 1156 thatare through-holes are formed in the securing section 1150 of the tripodbase attaching member 1180.

The body-side mount 200, the securing section 1150, and the securingsection 1110 have ring shapes corresponding to each other. The body-sidemount 200, the securing section 1150, and the securing section 1110,when aligned with each other, each have six screw holes that arepositionally fixed at the same positions in the xy plane. When in thealigned state, the body-side mount 200, the securing section 1150, andthe securing section 1110 are fastened together by the screw 231, thescrew 232, the screw 233, the screw 234, the screw 235, and the screw236. In a state where the securing section 1150 is sandwiched betweenthe body-side mount 200 and the body 1100, the tripod base attachingmember 1180 is secured to the body-side mount 200 and the body 1100.

Specifically, when the hole 221, the female thread 1121, and the hole1151 are in the aligned state, the screw 231 is inserted therethrough.When the hole 222, the female thread 1122, and the hole 1152 are in thealigned state, the screw 232 is inserted therethrough. When the hole223, the female thread 1123, and the hole 1153 are in the aligned state,the screw 233 is inserted therethrough. When the hole 224, the femalethread 1124, and the hole 1154 are in the aligned state, the screw 234is inserted therethrough. When the hole 225, the female thread 1125, andthe hole 1155 are in the aligned state, the screw 235 is insertedtherethrough. When the hole 226, the female thread 1126, and the hole1156 are in the aligned state, the screw 236 is inserted therethrough.In this way, the body 1100, the tripod base attaching member 1180, andthe body-side mount 200 are fastened together at six points.

In this way, the tripod base attaching member 1180 is secured to thebody-side mount 200. In particular, the body-side mount 200, the tripodbase attaching member 1180, and the body 1100 are secured at six pointspositioned in the same circle. Therefore, the stress placed on thetripod base 1170 from the tripod can be absorbed by the body-side mount200 via the tripod base attaching member 1180.

When the tripod base attaching member 1180 is secured between thebody-side mount 200 and the securing section 1110, such as in thisassembly example, the front cover 300 may be secured near the securingsection 1110. Other structures including the front cover 300, the topcover 400, and the back cover 500 can adopt the same structure asdescribed in relation to FIGS. 1 to 10.

FIG. 12 is an exploded perspective view schematically showing anotherassembly example of the tripod base assembly. In the present assemblyexample, components that are the same as components described inrelation to FIG. 11 are given the same reference numerals anddescriptions thereof are omitted.

A hole 221, a hole 222, a hole 223, a hole 224, a hole 225, a hole 226,a hole 227, and a hole 228 are formed in the body-side mount 1200. Thebody-side mount 1200 differs from the body-side mount 200 by includingthe hole 227 and the hole 228. The remaining structure of the body-sidemount 1200 may be the same as the structure of the body-side mount 200.The tripod base attaching member 1280 includes a securing section 1250and a tripod base attaching portion 1140. A hole 1254, a female thread1257, and a female thread 1258 are formed in the securing section 1250of the tripod base attaching member 1280.

The screw 231 is inserted through the hole 221 and the female thread1121. The screw 232 is inserted through the hole 222 and the femalethread 1122. The screw 233 is inserted through the hole 223 and thefemale thread 1123. The screw 234 is inserted through the hole 224, thehole 1254, and the female thread 1124. The screw 235 is inserted throughthe hole 225 and the female thread 1125. The screw 236 is insertedthrough the hole 226 and the female thread 1126.

The screw 237 is inserted through the hole 227 and the female thread1257. The screw 238 is inserted through the hole 228 and the femalethread 1258. In this way, the body-side mount 1200 and the tripod baseattaching member 1280 are fastened together by the screw 237 and thescrew 238 as well. With this assembly example as well, the stress placedon the tripod base 1170 can be absorbed by the body-side mount 1200 viathe tripod base attaching member 1280.

In the imaging device 10 described above, the imaging unit 160 includingan imaging element is used as an example of a light receiving unit thatreceives light passed through an interchangeable lens. The lightreceiving unit may be a focal point detection unit that includes asensor for detecting a focal state from a subject. The sensor of thefocal point detection unit may be a line sensor that detects a phasedifference. The light receiving unit may be a finder unit. The finderunit may include a photometric unit that includes a photometric sensorfor measuring the light amount from the subject. The finder unit mayhave a focus plate.

Among the imaging unit 160, the finder unit, and the focal pointdetection unit that are examples of the light receiving unit, a lightreceiving unit that is a combination of one or more of these units maybe secured to the body 100.

For example, a single light receiving unit may be secured to the body100. Specifically, the imaging unit 160 alone may be secured to the body100. The finder unit alone may be secured to the body 100. The focalpoint detection unit alone may be secured to the body 100. In any ofthese cases, the imaging device 10 need not include a light receivingunit other than the light receiving unit secured to the body 100. Forexample, the imaging device 10 may include just the imaging unit 160 asthe light receiving unit, and the imaging unit 160 of the imaging device10 may be secured to the body 100.

Instead, two or more light receiving units may be secured to the body100. For example, just the imaging unit 160 and the finder unit may besecured to the body 100. Just the imaging unit 160 and the focal pointdetection unit may be secured to the body 100. Just the finder unit andthe focal point detection unit may be secured to the body 100. In any ofthese cases, the imaging device 10 need not include a light receivingunit other than the light receiving units secured to the body 100. Forexample, the imaging device 10 may include just the imaging unit 160 andthe finder unit as light receiving units, and have the imaging unit 160and the finder unit of the imaging device 10 secured to the body 100.The imaging device 10 may include just the imaging unit 160 and thefocal point detection unit as the light receiving units, and have theimaging unit 160 and the focal point detection unit of the imagingdevice 10 secured to the body 100.

The body 100 may have three light receiving units secured thereto. Forexample, the imaging unit 160, the finder unit, and the focal pointdetection unit may be secured to the body 100. In this case, the imagingdevice 10 need not include any light receiving units other than thelight receiving units secured to the body 100. For example, the imagingdevice 10 may include just the imaging unit 160, the finder unit, andthe focal point detection unit as the light receiving units, and theimaging unit 160, the finder unit, and the focal point detection unit ofthe imaging device 10 may be secured to the body 100. In this case, theimaging device 10 may include further light receiving units in additionto the imaging unit 160, the finder unit, and the focal point detectionunit. In other words, the imaging device 10 may further include one ormore light receiving units that are not secured to the body 100.

In the present embodiment, a camera body that does not include a lensapparatus is provided as an example of the structure of the imagingdevice. However, the imaging device may include a camera body and a lensunit. In addition to the single-lens reflex camera that is one exampleof an interchangeable lens camera, the imaging device can be a varietyof types of cameras with interchangeable lenses. The imaging device isan example of a light receiving apparatus. The light receiving apparatusis not limited to an imaging device, and may be equipment other than animaging device.

While the embodiments of the present invention have been described, thetechnical scope of the invention is not limited to the above describedembodiments. It is apparent to persons skilled in the art that variousalterations and improvements can be added to the above-describedembodiments. It is also apparent from the scope of the claims that theembodiments added with such alterations or improvements can be includedin the technical scope of the invention.

The operations, procedures, steps, and stages of each process performedby an apparatus, system, program, and method shown in the claims,embodiments, or diagrams can be performed in any order as long as theorder is not indicated by “prior to,” “before,” or the like and as longas the output from a previous process is not used in a later process.Even if the process flow is described using phrases such as “first” or“next” in the claims, embodiments, or diagrams, it does not necessarilymean that the process must be performed in this order.

What is claimed is:
 1. An imaging device comprising: an imaging element;a member being secured to the imaging element; an exterior portioncovering at least a portion of the member; and a mount configured to beattachable to an interchangeable lens, the member and the exteriorportion being secured to the mount.